Abstracts

Introduction

Climate conditions can regulate plant interactions (Kikvidze et al., 2011KIKVIDZE, Z., MICHALET, R., BROOKER, RW., CAVIERES, LA., LORTIE, CJ., PUGNAIRE, FI. and CALLAWAY, RM., 2011. Climatic drivers of plant–plant interactions and diversity in alpine communities. Alpine Botany, vol. 121, no. 1, p. 63-70. http://dx.doi.org/10.1007/s00035-010-0085-x.
http://dx.doi.org/10.1007/s00035-010-008... ). Precipitation regime, temperature, humidity, radiation and soil moisture can affect plant secondary metabolism (Gobbo-Neto and Lopes, 2007GOBBO-NETO, L. and LOPES, NP., 2007. Plantas medicinais: fatores de influência no conteúdo de metabólitos secundários. Quimica Nova, vol. 30, no. 2, p. 374-381. http://dx.doi.org/10.1590/S0100-40422007000200026.
http://dx.doi.org/10.1590/S0100-40422007... ; Taiz and Zeiger, 2010TAIZ, L. and ZEIGER, E., 2010. Plant Physiology. 5th ed. Sunderland: Sinauer Associates Inc. 782 p.) and may relate to plant chemical interactions.

The Brazilian cerrado, the largest savanna in South America, once covered 22% of the country's land surface (22 million ha), primarily in its Central Plateau. It has a seasonal climate, with a dry season from April to September and a wet season from October to March (Gottsberger and Silberbauer-Gottsberger, 2006GOTTSBERGER, G. and SILBERBAUER-GOTTSBERGER, I., 2006. Life in the cerrado: origin, structure, dynamics and plant use: a South American tropical seasonal ecosystem. Ulm: Reta Verlag. 277 p.). During the former, the soil presents a surface water deficit (Haridasan, 2001HARIDASAN, M., 2001. Nutrient cycling as a function of landscape and biotic characteristics in the cerrado of central Brazil. In MCCLAIN, ME., VICTORIA, RL. and RICHEY, JE. The biogeochemistry of the Amazon basin. New York: Oxford University Press. p. 68-83.) that may result in a stressful situation for plants in this environment (Sarmiento, 1996SARMIENTO, G., 1996. Biodiversity and water relations in tropical savannas. In SOLBRIG, OT., MEDINA, E. and SILVA, JF. Biodiversity and savanna ecosystem processes: a global perspective. Berlin: Springer Verlag. p. 61-75. http://dx.doi.org/10.1007/978-3-642-78969-4_4.
http://dx.doi.org/10.1007/978-3-642-7896... ).

Abiotic and biotic stress conditions seemingly improve plant allelopathic activity (Gross, 2003GROSS, EM., 2003. Allelopathy of Aquatic Autotrophs. Critical Reviews in Plant Sciences, vol. 22, no. 3-4, p. 313-339. http://dx.doi.org/10.1080/713610859.
http://dx.doi.org/10.1080/713610859... ). Allelopathy is defined by the International Allelopathy Society (IAS, 2013) as any process involving secondary metabolites produced by plants, algae, bacteria and fungi that influences the growth and development of agricultural and biological systems. Allelopathy is strongly related to plant-environment interactions (Blanco, 2007BLANCO, JA., 2007. The representation of allelopathy in ecosystem-level forest models. Ecological Modelling, vol. 209, no. 2-4, p. 65-77. http://dx.doi.org/10.1016/j.ecolmodel.2007.06.014.
http://dx.doi.org/10.1016/j.ecolmodel.20... ). Allelochemicals can benefit or prejudice certain species, influencing the qualitative and quantitative floristic composition in time and space (Durigan and Almeida, 1993DURIGAN, JC. and ALMEIDA, FLS., 1993. Noções sobre a alelopatia. Jaboticabal: Funep. 28 p.). Furthermore, allelopathy may influence forest succession process (Peng et al., 2004PENG, SL., CHEN, ZQ., WEN, J. and SHAO, H., 2004. Is allelopathy a driving force in forest sucession? Allelopathy Journal, vol. 14, p. 197-204.) and spatial patterns of species distribution (Inderjit and Callaway, 2003INDERJIT and CALLAWAY, RM., 2003. Experimental designs for the study of allelopathy. Plant and Soil, vol. 256, no. 1, p. 1-11. http://dx.doi.org/10.1023/A:1026242418333.
http://dx.doi.org/10.1023/A:102624241833... ). Allelopathic influence can be expressed on seed germination and/or establishment and development of neighbouring individuals (Ferreira, 2005FERREIRA, AG., 2005. Alelopatia: sinergismo e inibição. In NOGUEIRA, RJMC., ARAÚJO, EL., WILLADINO, LG. and CAVALCANTE, UMT. Estresses ambientais: danos e benefícios em plantas. Recife: UFRPE, Imprensa Universitária. p. 433-440.).

Although seasonal allelopathic variation has been reported, few studies consider this issue for native cerrado species (Oliveira, 2009OLIVEIRA, SCC., 2009. Estudo alelopático de espécies do gênero Solanum do Distrito Federal. São Carlos: Departamento de Botânica, Universidade Federal de São Carlos. 163 p. Tese de Doutorado.; Orlandi et al., 2010ORLANDI, L., BARBOSA, S., ROCHA, LC., RODRIGUES, LCDA., BEIJO, LA. and SILVA, GA., 2010. Efeito do extrato foliar de murici-pequeno obtido em diferentes épocas do ano sobre aspectos vegetativos do bioteste alface. In Anais do XIX congresso de Pós-graduação da UFLA, Reunião Regional da SBPC: Ciência, Tecnologia, Inovação e o Município, 2010. Lavras. Lavras: UFLA.). It is necessary to examine seasonal allelopathic variation from several species. In this study, the allelopathic potential of eleven cerrado species from nine different families and two different collection periods were assessed to determine the existence and extent of seasonal variation.

Material and Methods

Collection, study area and climate

Mature plant leaves of eleven cerrado species were collected in a cerrado sensu stricto area of the Universidade Federal de São Carlos (21°8′5″S and 47°53′12″W), São Carlos, São Paulo, Brazil, on 30/03/2006 and 27/07/2006. This area is classified as Cwa (according to Köeppen (1948)KÖEPPEN, W., 1948. Climatologia. México: Fondo de Cultura Económica. 478 p.) with warm climate and dry winter. The average monthly pluviometry and temperature were 207 mm and 23°C during the rainy season (October 2005 - March 2006) and 18 mm and 20°C during the dry season (April - September 2006) (Embrapa, 2012).

The species studied were Anadenanthera falcata(Benth.) Speg. (Fabaceae), Davilla elliptica A.St.-Hil. (Dilleniaceae), Diospyros hispida A.DC. (Ebenaceae), Kielmeyera coriacea Mart. & Zucc. (Clusiaceae), Miconia albicans (Sw.) Steud. (Melastomataceae), Piptocarpha rotundifolia Baker (Asteraceae), Schefflera vinosa (Cham. & Schltdl.) Frodin & Fiaschi (Araliaceae), Senna rugosa(G.Don) H.S.Irwin & Barneby (Fabaceae), Siparuna guianensis Aubl. (Monimiaceae), Stryphnodendron polyphyllum Mart. (Fabaceae), and Xylopia aromatica Mart. (Annonaceae) (Ipni, 2012). These species present different habits, shrub or tree (Table 1), and the collection of the leaves was unsystematic.

Extract preparation

The leaves were dried at 55°C for 72 hours and stored in plastic bags at ambient temperature until use. Crude extracts (10% concentration: weight/volume) with dry leaves and distilled water were prepared and ground with an industrial blender for approximately one minute. The extracts were stored at an ambient temperature for three hours, filtered using a vacuum pump coupled to a Büchner funnel covered with filter paper (3 µm), and tested on the germination of lettuce (Lactuca sativa L.) and sesame (Sesamum indicumL.).

Germination bioassay

Thirty cypselas/seeds of the target species (lettuce/sesame) were placed in Petri dishes (9 cm diameter) containing a double layer of filter paper (3 µm) moistened with 5 mL of extract or distilled water (witness). All Petri dishes were sealed with PVC film. The lids were closed, and the Petri dishes were placed in a BOD incubator (light-dark cycle of 12 h-12 h, 20±1°C for lettuce, and 28±2°C for sesame). The germinated cypselas/seeds were counted at 12 h intervals for one week and at 24 h intervals until the tenth day of sowing. Seeds with 2 mm radicular protrusion were considered to be germinated and removed to avoid recounting. At the end of the tenth day, the germination percentage, rate and informational entropy were calculated (Santana and Ranal, 2004SANTANA, DG. and RANAL, M., 2004. Análise da germinação - um enfoque estatístico. Brasília: Editora Universidade de Brasília. 248 p.) as follows:

1. G(%) = (N/A).100, where: G = germination percentage; N = number of germinated seeds; and A = total number of sowed seeds.

2. R = 1/t, where: R = the germination rate (days^–1); t = average time of germination (t = Σ(n_i.t_i)/Σn_i, where: t_i = time of incubation, and n_i = number of seeds germinated between two consecutive times of observation, (t_i - 1) and (t_i)).

3. E = −Σ[f_i.log₂(f_i)], where E = informational entropy of germination, f_i= relative germination frequency, and f_i = n_i/Σn_i, n_i = number of seeds germinated between two consecutive times of observation, (t_i - 1) and (t_i).

Osmotic potential

The osmotic potentials of the extracts were measured (Micro-Osmette, model: 5004 automatic osmometer). A germination bioassay was set with the target species subjected to treatments of polyethylene glycol 6000 in concentrations of corresponding obtained osmotic potentials.

Data analysis

The experimental design was completely randomised with four repetitions. The data were compared by the Mann-Whitney test (α=0.05), using PAST version 2.5 software (Hammer et al., 2001HAMMER, Ø., HARPER, DAT. and RYAN, PD., 2001. PAST: Paleontological Statistics Software Package for Education and Data Analysis. Palaeontologia Electronica, vol. 4, no. 1, p. 1-9.).

Results

The plant extracts presented osmotic potential values between -0.020 and -0.207 MPa (Table 1). The tested PEG-6000 solutions (−0.1 and −0.2 MPa) had no influence on lettuce and sesame germination percentages, rates and informational entropies.

Lettuce experiment results are shown in Table 2. Germinability reductions in relation to the witness were stronger under the effects of D. elliptica and M. albicans extracts from the dry season. All species extracts from both seasons (rainy and dry) delayed the germination in relation to the witness. However, the germination rate was lower for dry season extracts of six species (D. elliptica, D. hispida, K. coriacea, M. albicans, P. rotundifolia and S. vinosa). Germination entropy was higher for dry season extracts of four species (D. hispida, K. coriacea, P. rotundifolia and S. vinosa). D. elliptica was the only species that presented rainy season extract with higher negative effects on entropy than the dry season extract.

Sesame experiment results are shown in Table 3. No differences in germinability were observed in any treatments. The germination rate was decreased in 10 out of 11 species extracts. Three species (D. elliptica, P. rotundifoliaand S. vinosa) presented higher inhibitions when collected in the dry season, compared with just one species (A. falcata) in the rainy season. Few differences in the germination entropy for this target species were observed. Four species increased entropy values, but only two species collected in the dry season had higher effects.

Discussion

The osmotic potential of an extract can present a negative effect on germination (Ferreira and Aquila, 2000FERREIRA, AG. and AQUILA, MEA., 2000. Alelopatia: uma área emergente da ecofisiologia. Revista Brasileira de Fisiologia Vegetal, vol. 12, p. 175-204.). Some solutes alter water osmotic potential and uptake by the plant (Villela et al., 1991VILLELA, FA., DONI FILHO, L. and SEQUEIRA, EL., 1991. Tabela de potencial osmótico em função da concentração de polietileno glicol 6000 e da temperatura. Pesquisa Agropecuaria Brasileira, vol. 26, no. 11-12, p. 1957-1968.). According to the osmolarity control experiment, the studied cerrado species extracts did not show osmotic potential values (from −0.020 to −0.207 MPa) that could influence lettuce and sesame germination processes.

The germination of lettuce and sesame were more impacted by dry season extracts. Decreases in the percentages and rates were more evident in target species subjected to dry season extracts. Stronger inhibitions occurred on the germination rate rather than the percentage. Higher germination entropy values and imbibition time distributions were verified, characterising lower germination synchrony. In addition to germinability, germination rate, homogeneity and synchrony are factors that show the level of organisation or disorder in the chemical reactions of the germination process (Ferreira, 2004FERREIRA, AG., 2004. Interferência: competição e alelopatia. In FERREIRA, AG. and BORGHETTI, F. Germinação do básico ao aplicado. Porto Alegre: Artmed. p. 251-262.; Santana et al., 2006SANTANA, DG., RANAL, MA., MUSTAFA, PCV. and SILVA, RMG., 2006. Germination measurements to evaluate allelopathic interactions. Allelopathy Journal, vol. 17, no. 1, p. 43-52.). Changes in germination parameters can result from the effects of several physiological processes: membrane permeability, DNA transcription and translation, second messengers function, respiration, enzymes and receptors conformation (Ferreira, 2004FERREIRA, AG., 2004. Interferência: competição e alelopatia. In FERREIRA, AG. and BORGHETTI, F. Germinação do básico ao aplicado. Porto Alegre: Artmed. p. 251-262.; Rizvi and Rizvi, 1992RIZVI, SJH. and RIZVI, V. (Eds.), 1992. Allelopathy: basic and applied aspects. London: Chapman & Hall. 480 p. http://dx.doi.org/10.1007/978-94-011-2376-1.
http://dx.doi.org/10.1007/978-94-011-237... ). Slower germination plants can present reduced size (Jefferson and Pennacchio, 2003JEFFERSON, LV. and PENNACCHIO, M., 2003. Allelopathic effects of foliage extracts from four Chenopodiaceae species on seed germination. Journal of Arid Environments, vol. 55, no. 2, p. 275-285. http://dx.doi.org/10.1016/S0140-1963(03)00028-4.
http://dx.doi.org/10.1016/S0140-1963(03)... ), leading to greater susceptibility to stress and less chances in resource competition. The species' sensibility to phytotoxins under laboratory conditions is dependent of biochemical/physiological characteristics (Kobayashi, 2004KOBAYASHI, K., 2004. Factors affecting phytotoxic activity of alelochemicals in soil. Weed Biology and Management, vol. 4, no. 1, p. 1-7. http://dx.doi.org/10.1111/j.1445-6664.2003.00112.x.
http://dx.doi.org/10.1111/j.1445-6664.20... ), seed size and structure.

Because phytotoxic effects on the germination processes can be species dependent (Oliveira, 2009OLIVEIRA, SCC., 2009. Estudo alelopático de espécies do gênero Solanum do Distrito Federal. São Carlos: Departamento de Botânica, Universidade Federal de São Carlos. 163 p. Tese de Doutorado.), two target species (lettuce and sesame) were selected. Dependency on both donor and receptor species was observed. Donor species differed in their effects; some species presented inhibitions on none, some or all of the germination parameters. The receptor species sesame was less sensible compared to lettuce but presented similar results of higher negative effect when subjected to dry season extracts. Lettuce has been considered to be too sensitive for allelopathic bioassays, and this study detected more differences in phytotoxic activities between the extracts from the rainy and dry season collection periods.

Cerrado presents a dry season that lasts up to six months (Gottsberger and Silberbauer-Gottsberger, 2006GOTTSBERGER, G. and SILBERBAUER-GOTTSBERGER, I., 2006. Life in the cerrado: origin, structure, dynamics and plant use: a South American tropical seasonal ecosystem. Ulm: Reta Verlag. 277 p.). The soil is subjected to a water deficit at the surface layers due to increasing atmospheric evaporation demand and solar incidence (Franco, 2002FRANCO, AC., 2002. Ecophysiology of woody plants. In OLIVEIRA, PS. and MARQUIS, RJ. The cerrados of Brazil: Ecology and natural history of a neotropical savanna. Irvington: Columbia University Press. p. 178-197.; Haridasan, 2001HARIDASAN, M., 2001. Nutrient cycling as a function of landscape and biotic characteristics in the cerrado of central Brazil. In MCCLAIN, ME., VICTORIA, RL. and RICHEY, JE. The biogeochemistry of the Amazon basin. New York: Oxford University Press. p. 68-83.) that represents a potential stressful time for plants (Sarmiento, 1996SARMIENTO, G., 1996. Biodiversity and water relations in tropical savannas. In SOLBRIG, OT., MEDINA, E. and SILVA, JF. Biodiversity and savanna ecosystem processes: a global perspective. Berlin: Springer Verlag. p. 61-75. http://dx.doi.org/10.1007/978-3-642-78969-4_4.
http://dx.doi.org/10.1007/978-3-642-7896... ). Biotic and abiotic stressful conditions alter the production of allelochemicals. Climatic parameters can affect the production of flavonoids (Chaves and Escudero, 1999CHAVES, N. and ESCUDERO, C., 1999. Variation of flavonoid syntheis induced by ecological factors. In INDERJIT, DAKSHINI, KMM. and FOY, CL. Principles and Practices in Plant Ecology – Allelochemical Interactions. Boca Raton: CRC Press. p. 267-285.) and increase cumarine concentration in some plants (Blanco, 2007BLANCO, JA., 2007. The representation of allelopathy in ecosystem-level forest models. Ecological Modelling, vol. 209, no. 2-4, p. 65-77. http://dx.doi.org/10.1016/j.ecolmodel.2007.06.014.
http://dx.doi.org/10.1016/j.ecolmodel.20... ). Flavonoids are found in nearly all vascular plants, and some flavonoids can affect germination (Iwashina, 2003IWASHINA, T., 2003. Flavonoid function and activity to plants and other organisms. Uchu Seibutsu Kagaku, vol. 17, no. 1, p. 24-44. http://dx.doi.org/10.2187/bss.17.24. PMid:12897458
http://dx.doi.org/10.2187/bss.17.24... ). In addition, plants are rarely exposed to only one stress (Einhellig, 1999EINHELLIG, FA., 1999. An integrated view of allelochemicals amid multiple stresses. In INDERJIT, DAKSHINI, KMM. and FOY, CL. Principles and practices in plant ecology: Allelochemical interactions. Boca Raton: CRC Press. p. 479-494.). Other factors, which possibly interact in this environment, include competition processes, microorganism activity, vegetation burning and leaves deciduousness influenced by seasonality.

Environments in stressful conditions may restrict plant growth, photosynthetic ratio and accumulate nonstructural carbohydrates. This may be one of the reasons contributing to increased production of carbon based defensive substances, which are secondary metabolism derivatives (Chaves and Escudero, 1999CHAVES, N. and ESCUDERO, C., 1999. Variation of flavonoid syntheis induced by ecological factors. In INDERJIT, DAKSHINI, KMM. and FOY, CL. Principles and Practices in Plant Ecology – Allelochemical Interactions. Boca Raton: CRC Press. p. 267-285.). The carbon/nutrient balance is confirmed because species growing in low nutrient/water availability environments produce high levels of tannins and phenols (Bryant et al., 1983BRYANT, JP., CHAPIN, FS. and KLEIN, DR., 1983. Carbon/nutrient balance of boreal plants in relation to vertebrate herbivory. Oikos, vol. 40, no. 3, p. 357-368. http://dx.doi.org/10.2307/3544308.
http://dx.doi.org/10.2307/3544308... ; Waring et al., 1985WARING, RH., MCDONALD, AJS., LARSSON, S., WIREN, A., ARWIDSSON, E., ERICSSON, A. and LOHAMMAR, T., 1985. Differences in chemical composition of plant growing at constant relative growth rates with stable mineral nutrition. Oecologia, vol. 66, no. 2, p. 157-160. http://dx.doi.org/10.1007/BF00379849.
http://dx.doi.org/10.1007/BF00379849... ).

Allelopathy can present an important function in arid environments. Allelochemicals in arid environments remain in the soil longer compared with humid environments, and their effects can be intensified when combined with the impact of low soil moisture (Einhellig, 1999EINHELLIG, FA., 1999. An integrated view of allelochemicals amid multiple stresses. In INDERJIT, DAKSHINI, KMM. and FOY, CL. Principles and practices in plant ecology: Allelochemical interactions. Boca Raton: CRC Press. p. 479-494.). The production of these compounds can increase in environments where burning is common, most likely due to physical damage to plants. Increased production can provide a higher inhibition on competitor/receptor plants and characterise an important plant defense mechanism (Einhellig, 1999EINHELLIG, FA., 1999. An integrated view of allelochemicals amid multiple stresses. In INDERJIT, DAKSHINI, KMM. and FOY, CL. Principles and practices in plant ecology: Allelochemical interactions. Boca Raton: CRC Press. p. 479-494.; Einhellig, 2004EINHELLIG, FA., 2004. Mode of allelochemical action of phenolic compounds. In MACÍAS, FA., GALINDO, JCG., MOLINILLO, JMG. and CUTLER, HG. Allelopathy - Chemistry and mode of action of allelochemicals. Washington: CRC Press. p. 217-238.).

The difference observed in the results can be due to species exposure to climate alterations or other seasonal stresses that induced greater allelochemical production. The allelopathic activity on both receptor species increased during the dry season for the majority of the studied cerrado plant species. Lettuce was the most sensible receptor species, and the germination rate was the most sensible parameter that showed this difference. These distinct responses to stressful situations in a complex environment, such as the Brazilian cerrado, may support species establishment and survival. Therefore, studies of other species are necessary to better understand this topic.

Acknowledgements

We are grateful to CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico) for supporting the research for the first author and for funding the Research Productivity Grant for the last author.

References

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